03.03 Nitrogen Oxides - Emissions and Pollution (Edition 1994)
Overview
Effect of Nitrogen Oxides
Nitrogen oxides are acidifiers. They are damaging to human health, cause damage to plants, buildings and monuments and are an essential contributor to the excessive formation of ozone and other health-endangering oxidants during the summer heat periods.
Nitrogen oxides and particularly nitrogen dioxide effect persons and animals. They cause irritations to the mucous membranes in the respiratory tract and can increase the risk of infection (c.f. Kühling 1986). Also cell changes have been observed (c.f. BMUNR 1987). Various epidemiological investigations have shown a connection between deterioration of the lung function, respiratory tract symptoms and increased nitrogen dioxide concentration (c.f. Nowak et al. 1994).
Limits
Since the beginning of the 80s, along with discussion around the damaging consequences of motor vehicle traffic for the environment, the pollution of the air with nitrogen oxides has also found increased attention. So the permissible pollution limits for nitrogen dioxide were sunk gradually to around 20 to 30 % in the course of several revisions to the First General Regulation of the Federal Pollution Control Law (Technical Instruction for Clean Air - TA-Luft)
Exceeding the pollution limits of the TA-Luft and/or the 22 BImSchV (Federal Pollution Control Regulations) can lead to measures being imposed on plants which have been identified the polluters. If the violation can not be associated a certain cause, the responsible authorities must set up an Air Purity Plan and place stiffer demands on the licensing of new plants with regard to the permissible emission.
Moreover the European Community, after limiting the concentration of sulfur dioxide, floating dust and lead in the air - with their Guideline from 7 March 1985 on Air Quality Standards, also determined a limit and guide value for nitrogen dioxide. In 1993 this 98 % limit was adopted in national law as Regulation 22 for the Implementation of the Federal Pollution Control Law.
Exceeding the limit of the EC Guideline are to be reported to the Council of the European Community. The national authorities must present plans for reaching the prescribed limits and a time limit for reaching them. Also should become the guide value of the EC Guideline is to be taken into account for all traffic - and building planning. While the EC limits are obligatory, Guide values and standard values serve as an orientation and have solely advisory character.
Moreover, in order to maintain the long-term capacity of the ecosystem, pollution limits must be observed, which take into account its sensitivity. Thus the filter effect through the surface structure of forests causes a high pollutant penetration and accumulation. The damaging nitrogen oxides and their by-products cause manifold effects on forest ecosystems. The forest damage research, since beginning of the 80s pursued intensely on an international plane, has delivered new knowledge in the area of pollution effects, which led to establishment a very critical limit. Limits were set by the UN-ECE 1992. These were values (critical levels, critical loads) at which no changes in structure and function of the ecosystem are to be expected. The Federal Republic of Germany belongs to the initial signatories and co-initiators of the treaty and has ratified the resolutions on new strategies for the European clean air policy.
Tab. 1: Limits, Standard Values and Recommendations for the Nitrogen Dioxide Pollution in the Air
Causes and Development of Nitrogen Oxide Emissions
Nitrogen oxide emissions are caused primarily by combustion processes in power plants and heavy industry firing plants as well as in motors. Nitrogen oxides develop from the nitrogen and the oxygen of the combustion air and to a lesser extent also through the oxidation of nitrogen-containing elements of the fuel. The formation of nitrogen oxides greatly increases with the combustion temperature. The primary polluters in Berlin are motor vehicle traffic with 19,000 t at approximately 50 % and the power plants as well as other licensed facilities with 16,000 t, or a share of more than 40 % (c.f. Fig. 1).
Fig. 1: Nitrogen Oxide - Emissions from the Individual Polluter Groups in Berlin (tons per year)
Nitrogen monoxide comprises more than 90 % of nitrogen oxide emissions. Above all it is the reaction with ozone in the atmosphere which forms the nitrogen dioxide so much more damaging to human health. Since these reactions use up ozone, conurbations display, on average, a slighter ozone concentration in the near-ground air than rural regions. Beside ozone, combinations with hydrocarbon molecules also contribute to the transformation of nitrogen monoxide into nitrogen dioxide. Through further oxidation and combination with hydrocarbon molecules acidic aerosols develop from nitrogen dioxide, which deposit on surfaces and/or precipitate from the atmosphere as acid rain.
Under the influence of intense sunlight reactions occur in the Atmosphere simultaneously, by which nitrogen dioxide decays again into Nitrogen monoxide and oxygen atoms. In this process, in which likewise water - and hydrocarbon molecules are involved, more near-ground ozone is produced than consumed. The ozone concentration in the air can rise thereby greatly (c.f. Map 03.06 SenStadtUmTech 1996a).
Verified data on the long-term development the nitrogen oxide emissions and pollution do not exist for Berlin. On the basis of measurements in Frankfurt am Main, an eightfold rise in the nitrogen oxide pollution must be assumed for the period from 1962 to 1976 (c.f. Umweltbundesamt 1989). Nitrogen oxides - like volatile hydrocarbons - have become essential components of air pollution since the end of the Second World War. On the other hand, sulfur dioxide and floating dust have always been a part of the air pollution in central Europe given the prevalent climatic conditions.
Development of Nitrogen Oxide Pollution
Since 1979, nitrogen oxide measurements in Berlin have been carried out by the Federal Health Agency in the west part of the city at the Schloss Strasse in Steglitz and by the District Hygiene Inspectorate Berlin in the east part at the Parochial Strasse in the Borough Mitte. As part of the Berlin Air Quality Monitoring Network (BLUME), nitrogen oxide measurements were also begun at a station in Wedding in 1984.
While the near traffic measurement at the Schloss Strasse is strongly effected by changing traffic conditions and allows no statement as to trends, the measurements at the low traffic Parochial Strasse, which are representative for medium-level inner city pollution, had shown until 1987 an average annual increase in the concentration of about 3.5 % (from 35 to 45 µg/m3in 8 years). Since 1987 both here as well as at other measuring stations in the city display an reduction (c.f. Fig. 2).
Fig. 2: The Yearly Average of Nitrogen Dioxide 1979 - 1995
The introduction of denitrifying measures in the large power and heating works (c.f. Tab. 2) as well as the introduction the regulated three-way catalytic converter in passenger cars are reasons for the decrease. The shift to vehicles with catalytic converters in Berlin has advanced especially quickly. In 1995, the share of cars equipped with catalytic converters in Berlin lay at 65 %.
Tab. 2:Commissioning of Desulfurization and Denitrification Plants in the Berlin Heating Power Plants (HKW) and Power Plants (KW) (as of August 1996)
In comparison to the very positive development with respect to sulfur dioxide (c.f. Map 03.01 SenStadtUmTech 1997a), the pollution development of nitrogen oxides has been unsatisfactory. The reason is the constant growth in traffic volume. About half the near ground nitrogen oxide emissions come from heavy transport vehicles and buses. For these vehicles, substantial improvements to reduce emissions of nitrogen oxides and other pollutants have only taken effect since 1 October 1996. Due to the expected increase in traffic, it must be assumed that the contribution of the polluter group traffic will be decisive in future for the development of nitrogen oxide pollution in the Berlin air.
Statistical Base
Emissions
In order to provide a differentiated evaluation of the causes of nitrogen oxide pollution and contribute toward their elimination, the Berlin Department of Urban Development, Environmental Protection and Technology maintains an emission data base for the principal polluter groups.
The data for the establishing the emission data base industry 1994 have been taken from the principal individual polluters (power-, heating power- and heating plants as well as all industrial plants requiring licenses) using their emissions declaration, according to the instructions the Federal Pollution Control Law must be submitted by to the pollution control authorities by the management every two years.
The emission data base domestic heating 1994 is laid out statistically for the multitude of small heating systems in the urban area. For all residential buildings, the heat requirements and the shares by heating type, e.g. coal ovens, oil-fired central heating, gas-floor heat, electric- and long-distance heat are determined based on the amount of built-up space. With the help of specific factors assigned to each heating type the emission of each individual housing block is determined. The heating demand satisfied by electric and district heating has not been taken into account if the heating is produced in licensed facilities which have been registered in the emission data base industry.
The emission data base traffic 1993 is based on traffic survey on the part of the traffic administration as well as on statements as to the motor vehicle inventory and the average road performance of the motor vehicles. The emission is calculated with the help of factors, which are determined for different vehicle classes. Thereby passenger cars and delivery vehicles with four-stroke engines with and without exhaust fume cleaning are distinguished from those with two tact - or diesel motors as well as heavy transport vehicle and buses.
All estimates and calculations are compared with the energy balance, in which the entire consumption of fuels in Berlin is compiled.
Calculated Pollution
The pollution calculations were undertaken with the help of a computer-supported of meteorological dispersion model for large individual polluters. The polluter groups domestic heating and traffic (c.f. Fath et al. 1991). were calculated separately.
For the dispersion calculations the domestic heating and traffic emissions were distributed on a grid of 1 x 1 km. Fixed emission levels are attributed to them, while the large individual polluters have been entered with the respective chimney location and the smoke stack height in the calculations. The calculations assume that the pollutant particles contained in the trails of smoke are transported with the wind and expand vertically for the central transport direction vertically and horizontally in the form of a normal distribution. This pollution can only so far disperse until a temperature inversion prevents further dispersion. The calculations take into account wind direction, wind speed, turbulent dispersion capacity in the atmosphere and the inversion altitude. In addition, it is assumed that the heating requirements and thus also the pollutant emission greatly increase in the winter with decreasing temperature.
Since the model calculations assume an unlimited expansion of the pollutants and the domestic heating- and traffic emissions are assigned to the all-inclusive 1 x 1 km grid, the calculation at the nearest measuring points represent results, which are ordered in greater distance from pollutant sources, particularly streets. The pollutant concentration is calculated for about 100 surface points distributed throughout the entire urban area.
Fig. 3:98 % Values of NO2 -Pollution in Typical Traffic Corridors of the Berlin Inner City (background- and additional motor vehicle-induced pollution). The street names indicated represent selected traffic corridor segments (IVU 1993).
In connection with the application of the EC Guideline for nitrogen dioxide and the draft of 23 BImSchV, increased measurement of the pollutant load in traffic corridors and at traffic concentrations has been begun to be determine using dispersion calculations. Figure 3 shows the calculated concentrations in 15 traffic corridors of the Berlin inner city. These were determined with the help of a specific dispersion model developed on behalf of the Federal Environment Agency (Umweltbundesamt). The calculations for the year1993/94 show that only a few streets in Berlin can be expected to exhibit nitrogen dioxide levels in excess of those set in the draft assessment from 23 BImSchV of 160 µg/m3 (c.f. Map 03.10 SenStadtUmTech, in preparation).
Measured Pollution
In 1995, pollution measurements for nitrogen monoxide, nitrogen dioxide and the sum of nitrogen oxides were taken at 27 stations in Berlin.
Automatic measuring instruments are used, which are continuously in service and transmit their data in three minute sequence by telephone lines to the central computer of the Berlin Air Quality Monitoring Network. In the measuring instruments, ozone is added in high concentration to the measured air. With the help of photo sensors the light quantity is measured. This appears as chemical luminescence, if nitrogen monoxide reacts with ozone. The nitrogen dioxide concentration is registered with this process, in that one conducts half of the measured gas through a catalyst, by which the nitrogen dioxide is transformed into nitrogen monoxide (c.f. SenStadtUm 1995).
To obtain information as to the distribution of the pollution in the urban area, 16 stations are ordered in that 4 x 4 km grid in the populous inner-city residential areas as well as in the more suburban transition area. Five stations lie in the Grunewald and in the northern and southern outskirts. According to the instructions for the measurement and evaluation of the pollutant load, these stations have been arranged in more than 20 m distance from pollutant sources. One station can be found at approximately 300 m above the surface on the Frohnau broadcasting tower in the northern part of the city. It serves to record the pollution of national origin.
Five stations (No. 14 in Charlottenburg, No. 74 and No. 174 in Friedrichshain, No. 117 in Steglitz and No. 220 in Neukölln) lie in main traffic arteries in the area of sidewalks. With them representative data are collected about the near street air pollution caused above all by motor vehicle traffic.
Methodology
The data on the 1 x 1 km emissions of nitrogen oxide are depicted both as a color grid and as an absolute value. The color depiction uses rounded-off numbers.
The polluter-related calculated pollution is depicted to match the presentation of the sum of nitrogen oxide emissions for 1994 resp. 1993. These have been determined with the help of the above described dispersion calculations and using a normal distribution approach as described in the TA-Luft.
Since the pollution measurements are taken continuously, those for the current year 1995 could be selected. The nitrogen oxides are presented the measured pollution as yearly average of the sum in the comparison with the results of the dispersion calculations and as nitrogen dioxide to the comparison with the limits. For NO2the limits IW1and IW2of TA-Luft 1986 were set as class values for the delimitation the highest class. They were compared to the reference values I1(yearly average) and I2(98 % value).
The interpolation of the isolines resulted per hand. The fact that stations were influenced differently from those near main traffic arteries was taken into account. In addition, the respective values are presented BLUME - measurement stations, distinguished according to type of the stations.
Map Description
Emissions and Calculated Pollution
In the three Maps 03.03.1, 03.03.2 and 03.03.3, the emissions for the primary polluter groups industry, domestic heating and traffic are presented for the year 1994 resp. 1993, each in 1 x 1 km- Grid. The Maps 03.03.4, 03.03.5 and 03.03.6 give respectively the calculated yearly average for pollution concentrations in 1994 resp. 1993 from those main polluter groups.
Industry 1994
The Map 03.03.1 of the industry emissions 1994 shows a very irregular picture. It influenced above all through the twelve power-, heating power- and heating plants, which are distributed throughout the whole city and display relative high emissions. The highest grid value, with more than 2,000 t/km2and year, can be found at the heating power plant Reuter. It still lies at only a third of the 1989 maximum value (c.f. Map 03.03 SenStadtUm 1994b). This change, which is recognizable at the majority of major polluter sites demonstrates significantly the effect of the emission reduction measures shown in Table 2.
Since according to TA-Luft the height of industry smokestack is dependent on how heavy their pollution emission is; the heavier the pollution, the higher the smokestack. Thereby, the pollutants of these plants are discharged at higher elevations and distributed evenly in and over the entire urban area and the surrounding countryside. Therefore increased concentrations in the vicinity of the plants are as a rule neither calculated near, as Map 03.03.4 shows, nor measured, as Map 03.03.8 documents.
However, Map 03.03.4 shows only minimal influence of industrial plants on nitrogen oxide pollution. It shows two flat maximum values between 5 and 6 µg/m3 in the western city center and with respect to the main leeward wind direction at the eastern city perimeter. A value of between 1 and 3 µg/m3 has been calculated for the other areas at the city's edge.
Domestic Heating 1994
The Map 03.03.2 of domestic heating emissions 1994 shows in the inner city area a ring of higher nitrogen oxide values, which lies at a relative minimum in the center of town. The low values in the center are due to the influence of the Grosse Tiergarten and a high share of long-distance heat. The ring of higher values, with maximums of 20 to 30 t/km2and year in Prenzlauer Berg and in the parts of Wilmersdorf resp. in Kreuzberg and Neukölln, is caused through a high share of oil and coal-fueled single- and central heat at very high residential density. With the decrease in residential density, the emissions also decline in the direction of the city edges. The more densely-settled outskirts of the city in direction West (Spandau), North (Tegel), Southeast (Treptow) and Southwest (Zehlendorf) can be recognized by their slightly higher values. The large settlements Märkisches Viertel, Hellersdorf and Marzahn as well as Gropiusstadt do not show up as emission maximums because they are provided with long distance energy (c.f. Maps 08.01 and 08.02 SenStadtUmTech 1996b resp. 1996c). The same distribution, limited to West Berlin, already appeared in the Environmental Atlas of 1985, whereby the single values in the highly polluted areas lay up to 10 t/km2and year higher (c.f. Maps 03.03.2 and 03.03.5 SenStadtUm 1985).